A single-base-pair substitution abolishes D-amino-acid oxidase activity in the mouse.

Mutant ddY/DAO- mice lacking D-amino-acid oxidase (DAO) activity were examined for the cause of their lack of enzyme activity. Total RNA was extracted from the kidney of the ddY/DAO- mice and cDNA was synthesized. After cDNA encoding DAO was amplified by the polymerase chain reaction it was cloned into a plasmid and sequenced. Comparison of the DAO cDNA sequence with that of normal BALB/c mice revealed the presence of a single-base substitution (G----A) which causes a Gly-181----Arg substitution in the middle of the enzyme molecule. The mutant DAO cDNA was inserted into an expression vector and was expressed in transfected COS-1 cells. The transfected cells synthesized the DAO mutant protein, but they did not show DAO activity. In contrast, when cells were transfected with an expression vector carrying wild-type DAO cDNA, where the substituted base-pair was replaced by a normal base-pair, they showed DAO activity. These results indicate that the single base-pair substitution is the cause of the loss of DAO activity in the ddY/DAO- mice.     

Involvement of D-amino acid oxidase in elimination of free D-amino acids in mice.

The physiological role of D-amino acid oxidase was investigated by using mutant ddY/DAO- mice lacking the enzyme. Free D-amino acid concentrations in the mutant mice were significantly higher than those of control ddY/DAO+ mice in kidney, liver, lung, heart, brain, erythrocytes, serum and urine. The results suggest that the enzyme is involved in the catabolism of free D-amino acids in the body, and that free D-amino acids are also excreted into urine.     

Determination of free D-proline and D-leucine in the brains of mutant mice lacking D-amino acid oxidase activity.

A new procedure to accurately measure a trace amount of d-proline in biological samples has been developed. This D-amino acid was derivatized with 4-fluoro-7-nitro-2,1,3-benzoxadiazole and was determined by a column-switching HPLC system, a combination of a micro-ODS column and a chiral column. The detection limit for D-proline spiked in a mouse cerebrum sample is 1 fmol (injection amount, S/N = 3). Within-day precision and day-to-day precision obtained for spiked d-proline (10 fmol) are 2.14 and 5.35% (RSD), respectively. Using the new method, the amount of free D-proline in eight brain regions and sera of mutant ddY/DAO- mice, lacking D-amino acid oxidase activity, and control ddY/DAO+ mice was determined. The amount of free D-leucine was also investigated. The amount and distribution of D-proline in the brains of ddY/DAO+ mice and ddY/DAO- mice are almost the same, and relatively high amounts of D-proline have been observed in the pituitary gland and in the pineal gland. On the other hand, the amount of D-leucine is different between the two strains. In the brains of ddY/DAO+ mice, a relatively high amount of D-leucine has been observed in the pineal gland compared with other regions. In the brains of ddY/DAO- mice, D-leucine amounts are approximately 10 times higher than those obtained in ddY/DAO+ mice and regional difference has not been observed, while the amounts of L-proline and L-leucine are not significantly different between the two strains. In the serum, the amounts of both free D-proline and d-leucine are significantly higher in the ddY/DAO- mice than those obtained in ddY/DAO+ mice.     

Linkage of the Dao-1 gene for D-amino-acid oxidase to the pgm-1 gene for phosphoglucomutase-1 on the mouse chromosome 5

Linkage of the Dao-1 gene controlling D-amino-acid oxidase to the Pgm-1 gene controlling phosphoglucomutase-1 on the mouse chromosome 5 was examined. Mutant ddY/DAO- mice carrying a null Dao-1c allele had a Pgm-1a allele. Mutant mice were crossed to C3H/HeN and NZB/Kl mice carrying the Dao-1+ and Pgm-1b alleles. The hybrid F1 mice were backcrossed to the ddY/DAO- and their progeny were examined for alleles for D-amino-acid oxidase and phosphoglucomutase-1. In both backcrosses, the progeny with recombinant-type combinations of the alleles were significantly less than the progeny with the parental-type combinations, indicating the linkage of the Dao-1 and Pgm-1 genes. The recombination frequency between these loci was estimated to be 19.8 +/- 4.0%.     

Mouse Mutant Deficient in d-Amino Acid Oxidase Activity

D-Amino acid oxidase activity in the kidney homogenates of mice of seven strains was measured to search for a mutant for this enzyme. There was a consistent sex difference in the enzyme activity in these strains: male mice showed higher levels of the enzyme activity than females. In contrast to other strains, some mice of the ddY strain did not possess enzyme activity. This trait was inheritable, and a mouse stock without enzyme activity (DAO-) was established. The allele (Dao-1c) carried by the DAO- mice was recessive and behaved as a single autosomal gene in inheritance. Heterozygous mice for this gene (Dao-1+/Dao-1c) showed nearly half the enzyme activity of the wild-type homozygotes (Dao-1+/Dao-1+), suggesting that Dao-1c is a null allele and that there is a gene dosage effect on the enzyme activity.     

Brain and Kidney d-Amino Acid Oxidases Are Coded by a Single Gene in the Mouse

Mutant mice (ddY/DAO-) lacking D-amino acid oxidase in the kidney also lacked this enzyme in the brain. Genetic cross experiments showed that the inheritance of the enzyme in the brain was the same as that in the kidney. The deficiency in the enzyme in the brain could not be separated from that in the kidney. The brain and kidney enzymes showed similar substrate specificities. These results suggest that brain and kidney D-amino acid oxidases are coded by the same gene in the mouse.     

d-Aminoaciduria in mutant mice lackingd-amino-acid oxidase activity

Summary Urine of mutant ddY/DAO^– mice lackingd-amino-acid oxidase activity contained more serine and proline than that of normal ddY/DAO⁺ mice.d-Amino-acid oxidase treatment of urinary amino acids decreased the serine and proline, suggesting that they containedd-isomers. An HPLC analysis confirmed the presence ofd-serine. Urinary serine and proline contents were not decreased when the ddY/DAO^– mice were fed a diet which did not contain supplementaryd-methionine or when they were given water containing antibiotics. These results suggest that thed-serine andd-proline do not derive from thed-methionine supplemented in the diet or from intestinal bacteria. In urine of the ddY/DAO^– mice, a substance which seemed to bed-methionine sulfoxide and/ord-methionine sulfone was present. It is probably a metabolite of thed-methionine supplemented in the diet. Thed-aminoaciduria in the mutant mice lackingd-amino-acid oxidase activity indicates that this enzyme is involved in the metabolism of thed-amino acids in normal mice.     

Spontaneous excretion of D-alanine in urine in mutant mice lacking D-amino-acid oxidase.

Urine from mutant mice lacking D-amino-acid oxidase contained a large amount of alanine compared with that from normal mice. Urinary alanine of the mutant mice was sensitive to D-amino-acid oxidase. H.p.l.c. showed that about 94% of the urinary alanine had the D-configuration. These results suggest that D-amino-acid oxidase functions to decompose D-amino acid(s) in normal mice.     

Inhibition of <Emphasis Type="SmallCaps">d</Emphasis>-Amino-Acid Oxidase Activity Induces Pain Relief in Mice

(1). We investigated the effects of inhibiting d-amino-acid oxidase (DAO) activity on nociceptive responses through the use of mutant ddY/DAO⁻ mice, which lack DAO activity, and through the application of a selective inhibitor of DAO, sodium benzoate, in the tail flick test, hot-plate test, formalin test, and acetic acid-induced writhing test. (2). Compared with normal ddY/DAO⁺ mice, ddY/DAO⁻ mice showed significantly prolonged tail withdrawal latency in the tail flick test and licking/jumping latency in the hot-plate test, as well as significantly reduced duration of licking/biting in the late phase of the formalin test and the number of abdominal writhing in the acetic acid-induced writhing test. (3). In addition, we investigated the effects of sodium benzoate in Kunming mice having normal DAO activity. (4). Intravenous administration of sodium benzoate (400 mg/kg) significantly inhibited pain responses of the late phase of the formalin test and abdominal writhing responses in the acetic acid-induced writhing test, with no effects on the early phase flinch responses in the formalin test, nociceptive responses in the tail flick test, or hot-plate test. (5). These results suggest that DAO acts as a pro-nociceptive factor in pain, particularly chronic pain, transmission and modulation, and may be a target for pain treatment.     

Presence of D-amino-acid oxidase protein in mutant mice lacking D-amino-acid oxidase activity.

1. Mutant mice lacking D-amino-acid oxidase activity were examined as to whether they possessed the enzyme protein. 2. Immunoblotting using an antibody against hog kidney D-amino-acid oxidase showed that kidney homogenates of the mutant mice as well as that of the normal mice had proteins reactive to the antibody. 3. Peroxisomal proteins of the kidney cells of the mutant mice were not different from those of the normal mice. 4. The peroxisomes of the mutant mice possessed a protein reactive to the antibody in the immunoblotting whose size was the same as the D-amino-acid oxidase protein present in the peroxisomes of the normal mice. 5. These results suggest that the mutant mice synthesize the D-amino-acid oxidase protein and integrate it into peroxisomes, though it is a nonfunctional enzyme.     

THE INFLUENCE OF EXCESS METHIONINE ON THE FREE AMINO ACIDS OF BRAIN AND LIVER OF THE WEANLING RAT*

Abstract— —High circulating levels of l -methionine produced by inclusion in the diet or parenteral injection of the amino acid caused alterations in the free amino acid pattern of liver and brain tissues. Acute effects following l -methionine injection were more pronounced than those following long term feeding where adaptation played a role. The net effect following parenteral injection was to increase the total free amino acids of liver while decreasing those of brain. Individually, hepatic levels of aspartic acid, threonine, serine, glutamine, glutamic acid, glycine, and alanine were depressed while levels of taurine, cystathionine, methionine, lysine, and ornithine were markedly elevated. Brain levels of aspartic acid, threonine, serine, glutamic acid, glycine, alanine, and γ-aminobutyric acid were markedly depressed and increased levels of cystathionine, methionine, lysine, and glutamine were observed. A generalized aminoaciduria occurred shortly after excessive methionine intake. Disruption of the free amino acid pools was of two kinds. The first depended on the continued presence of excess l -methionine, the second did not.     

Chemotaxis toward amino acids in Escherichia coli

Escherichia coli cells are shown to be attracted to the l-amino acids alanine, asparagine, aspartate, cysteine, glutamate, glycine, methionine, serine, and threonine, but not to arginine, cystine, glutamine, histidine, isoleucine, leucine, lysine, phenylalanine, tryptophan, tyrosine, or valine. Bacteria grown in a proline-containing medium were, in addition, attracted to proline. Chemotaxis toward amino acids is shown to be mediated by at least two detection systems, the aspartate and serine chemoreceptors. The aspartate chemoreceptor was nonfunctional in the aspartate taxis mutant, which showed virtually no chemotaxis toward aspartate, glutamate, or methionine, and reduced taxis toward alanine, asparagine, cysteine, glycine, and serine. The serine chemoreceptor was nonfunctional in the serine taxis mutant, which was defective in taxis toward alanine, asparagine, cysteine, glycine, and serine, and which showed no chemotaxis toward threonine. Additional data concerning the specificities of the amino acid chemoreceptors with regard to amino acid analogues are also presented. Finally, two essentially nonoxidizable amino acid analogues, alpha-aminoisobutyrate and alpha-methylaspartate, are shown to be attractants for E. coli, demonstrating that extensive metabolism of attractants is not required for amino acid taxis.     

D-Amino acid metabolism in mammals: biosynthesis, degradation and analytical aspects of the metabolic study

It was believed for long time that d-amino acids are not present in mammals. However, current technological advances and improvements in analytical instruments have enabled studies that now indicate that significant amounts of D-amino acids are present in mammals. The most abundant D-amino acids are D-serine and D-aspartate. D-Serine, which is synthesized by serine racemase and is degraded by D-amino-acid oxidase, is present in the brain and modulates neurotransmission. D-Aspartate, which is synthesized by aspartate racemase and degraded by D-aspartate oxidase, is present in the neuroendocrine and endocrine tissues and testis. It regulates the synthesis and secretion of hormones and spermatogenesis. D-Serine and D-aspartate bind to the N-methyl-D-aspartate (NMDA) subtype of glutamate receptors and function as a coagonist and agonist, respectively. The enzymes that are involved in the synthesis and degradation of these D-amino acids are associated with neural diseases where the NMDA receptors are involved. Knockout mice for serine racemase and D-aspartate oxidase have been generated, and natural mutations in the d-amino-acid oxidase gene are present in mice and rats. These mutant animals display altered behaviors caused by enhanced or decreased NMDA receptor activity. In this article, we review currently available studies on D-amino acid metabolism in mammals and discuss analytical methods used to assay activity of amino acid racemases and D-amino-acid oxidases.     

Amino-acid synthesis in adult Dacus oleae (Gmelin) (Diptera Tephritidae) determined with [U-14C] glucose

The ability of adult Dacus oleae for amino-acid synthesis from [U-14C] glucose was investigated. The relatively high specific activity radiometric measurements indicated that both sexes were able to synthesize the amino acids: alanine, aspartic acid, cystine, glutamic acid, glycine, hydroxyproline, proline and tyrosine; therefore, these amino acids are considered as nutritionally dispensable for D. oleae. On the other hand, the amino acids: arginine, histidine, leucine, isoleucine, lysine, methionine, phenylalanine, serine, threonine, and valine, showed a very low specific activity and therefore are considered as nutritionally indispensable. It was not possible to conclude about tryptophane, since the acid hydrolysis destroyed this amino acid.     

Role of renal D-amino-acid oxidase in pharmacokinetics of D-leucine

d-Amino acids are now recognized to be widely present in mammals. Renal d-amino-acid oxidase (DAO) is associated with conversion of d-amino acids to the corresponding alpha-keto acids, but its contribution in vivo is poorly understood because the alpha-keto acids and/or l-amino acids formed are indistinguishable from endogenous compounds. First, we examined whether DAO is indispensable for conversion of d-amino acids to their alpha-keto acids by using the stable isotope tracer technique. After a bolus intravenous administration of d-[(2)H(7)]leucine to mutant mice lacking DAO activity (ddY/DAO(-)) and normal mice (ddY/DAO(+)), elimination of d-[(2)H(7)]leucine and formation of alpha-[(2)H(7)]ketoisocaproic acid ([(2)H(7)]KIC) and l-[(2)H(7)]leucine in plasma were determined. The ddY/DAO(-) mice, in contrast to ddY/DAO(+) mice, failed to convert d-[(2)H(7)]leucine to [(2)H(7)]KIC and l-[(2)H(7)]leucine. This result clearly revealed that DAO was indispensable for the process of chiral inversion of d-leucine. We further investigated the effect of renal mass reduction by partial nephrectomy on elimination of d-[(2)H(7)]leucine and formation of [(2)H(7)]KIC and l-[(2)H(7)]leucine. Renal mass reduction slowed down the elimination of d-[(2)H(7)]leucine. The fraction of conversion of d-[(2)H(7)]leucine to [(2)H(7)]KIC in sham-operated rats was 0.77, whereas that in five-sixths-nephrectomized rats was 0.25. The elimination behavior of d-[(2)H(7)]leucine observed in rats suggested that kidney was the principal organ responsible for converting d-leucine to KIC.     

Origin ofd-serine present in urine of mutant mice lackingd-amino-acid oxidase activity

Summary Urine of ddY/DAO mice lackingd-amino-acid oxidase contained 5.7 times more serine than that of normal ddY/DAO⁺ mice. Most of the serine wasd-isomer. The origin of this^d-serine was examined. Oral administration of 0.02% amoxicillin and 0.004% minocycline to the ddY/ DAO^- mice for 7 days did not reduce the urinaryd-serine, indicating that thed-serine was not of intestinal bacterial origin. When the mouse diet was changed to one with different compositions, the urinaryd-serine was considerably reduced. Furthermore, starvation of the ddY/DAO^- mice for 24 hours reduced the urinaryd-serine to 33% of the original level. These results indicate that most of the urinaryd-serine comes from the diet. However, the urine of the starved ddY/DAO^- mice still contained 4.6 times mored-serine than that of the ddY/DAO⁺ mice, suggesting a part of the D-serine have an endogenous origin.     

Amino acid synthesis from glucose-U-14C in Glossina morsitans

Amino acid synthesis from glucose-U-¹⁴C was investigated in 2 day post-emergent and pregnant females of Glossina morsitans. This insect can synthesize alanine, aspartic acid, cystine, glutamic acid, glycine, proline, and serine from glucose. Arginine, histidine, hydroxyproline, isoleucine, leucine, lysine, methionine, phenylalanine, taurine, threonine, and valine showed no radioactivity and hence may be classified as nutritionally indispensable amino acids. Although tyrosine and hydroxyproline were not synthesized from glucose, they are at least partially dispensable nutrients for this insect because their synthesis from phenylalanine has been demonstrated. After the labelled glucose injection the highest radioactivity was recovered in the proline fraction. This is probably related to its rôle as an important energy reserve for flight. The radioactive amino acids recovered from females and from their offspring following glucose-U-¹⁴C injection were similar to those recovered from younger females. Radioactivity was also detected in the expired CO₂ and the excreta. The amino acids alanine, arginine, cystine, glycine, histidine, leucine/isoleucine, lysine, methionine, proline, and valine were identified in the excreta, of which arginine and histidine were in the largest amounts. Only excreted alanine, glycine, and proline showed radioactivity.     

Carrier Protein-mediated Transport of Neutral Amino Acids into Mung Bean Mitochondria

The transport of neutral amino acids into mitochondria isolated from the hypocotyl of mung bean (Roxb.) was studied by the swelling technique. Isolated mitochondria swelled when added to an isosmotic solution of proline, serine, methionine, threonine, alanine, and glycine. The swelling was stereospecific in that it was faster in the l-amino acid than in the corresponding d-amino acid. Preincubation of the mitochondria with the sulfhydryl modifying reagents, p-mercuribenzoate and mersalyl, resulted in an inhibition of the swelling caused by proline, serine, threonine, and glycine. The swelling induced by alanine was inhibited only by mersalyl, whereas that by methionine was inhibited only by p-mercuribenzoate. In all cases, the inhibition caused by the sulfhydryl modifying reagents was readily reversible by the subsequent treatment of the mitochondria with dithiothreitol. N-Ethylmaleimide, another sulfhydryl-modifying reagent, did not cause any inhibition of the swelling. The findings indicate the existence of a protein mediated mechanism for the transport of neutral amino acids into plant mitochondria.     

不同晶型、旋光型氨基酸原料药的红外图谱分析

分析比较了 33种不同来源的氨基酸产品红外图谱的差异 ,其中丝氨酸、门冬氨酸、醋酸赖氨酸、谷氨酸 (白色结晶性粉末 )、苏氨酸、缬氨酸、丙氨酸、亮氨酸、脯氨酸、盐酸组氨酸、盐酸精氨酸、酪氨酸、胱氨酸等 13种与标准图谱完全一致 ;甲硫氨酸、盐酸赖氨酸、甘氨酸、谷氨酸 (白色结晶 )等 4种与标准图谱不一致 ,其原因是 :甘氨酸和谷氨酸由晶型不同造成 ,甲硫氨酸因旋光性不同而造成 ,盐酸赖氨酸与相应的生化试剂图谱一致。